SU1682563A1 - Method for working thick steep and inclined coal seams - Google Patents

Abstract

This invention relates to underground mining of coal seams using shield method. The goal is to increase the efficiency of coal extraction by providing control of the shield movement. The coal was removed by excavation machines under the protection of the shield. Carry out a ditch of the ventilation ditch near the soil of the reservoir and draw up a supporting pillar of the soil of the reservoir and a ledge on the opposite side of the ditch along the entire length of the slab above the reference pillar. Simultaneously with the notch, the ditches form a horizontal berm and supporting pillar from the side of the roof of the seam. From the side of the reservoir soil, the shield is supported by a mechanized support, which is installed on the ledge and the supporting rear sight of the reservoir soil. From the side of the roof of the seam, the shield is supported by a mechanized support, which is mounted on a horizontal berm. Work out supporting pillars with the subsequent lowering of the shield. Shield movement control from the side of the reservoir soil is carried out by moving the mechanized support after ditching for a step of shifting, after which coal is dug in the supporting rear section of the roof of the reservoir and, as it is removed, control of the shield movement is performed by unloading the mechanized support on the horizontal berm. Repulsed coal from the bottom is transported and coal-fired furnaces. 4 il.

Description

The invention relates to the mining industry and can be used in the development of thick coal seams with a shield system with a mechanized coal excavation.

The purpose of the invention is to increase the efficiency of coal extraction by providing control of the movement of the shield.

Figure 1 shows the stage of the excavation of the supporting rear sight and shifting sections of the shield; figure 2 - the same position after shifting

shield panel sections; on fig.Z - notch berm and ditch; figure 4 - shifting sections of the shield.

The method is carried out as follows.

The coal extraction under the shields 1 on steep seams is carried out using a shield mechanized complex that mechanizes the extraction of the ventilation ditch 2 and the supporting pillars 3 and 4 formed at the roof and the soil of the formation with coal transportation to coal 00

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Flame furnaces located on the flanks of the shield slab. The coal excavation at the roof of the reservoir is carried out by a excavation machine 5, located on the horizontal platform 6 recreated in each cycle. At the same time, the coal excavation in the supporting rear sight 3 and the horizontal platform 6 (berm) 6 are either driven by one machine 5 or by another separate machine. A part of the panel overlap 1, under which the supporting pillar 3 is removed from the roof of the reservoir, is supported by a mobile hydraulic support 7 mounted on the berm b and aggregated with the excavation machine 5 and equipped with a ring conveyor 8. The excavation of the coal in the ditch 2 is carried out by the excavation and hauling machine 9 frontal (pipeline) or flank action with delivery of coal to coal-fired furnaces through hydrotransport.

The maintenance and movement of the shield overlap 1 at the soil of the formation is carried out with a hydroficated crepe 10.

Shield overlap 1 consists of separate sections 11, interconnected by means of hinges, made in the form of cylindrical axes 12, defined together with sections 11 by cable ties 13. Each section 11 of the shield is made in the form of a wooden nakatnik package 14, bonded together by means of metal holes 15. The width of the section along the strike of the formation is 1.5-2.0 m.

The hydrated support 10 consists of a base beam 16, which is connected with each section 11 of the shield by hydraulic jacks 17 of the advancing and spacer hydraulic jacks 18 to the vertices of the hard supporting triangles 19, which each shield section is provided with. To the top of rigid support triangles 19 pivotally fasten t supporting berm hydraulic racks 20 with shoes

21. Spraying hydraulic jacks 18 and supporting hydroracks 20 are hingedly connected to each other by shunting hydraulic jacks

22. Hydraulic lined 10 in each section of the shield has a spatial shape, because the hydraulic rails 20, hydraulic jacks 18.17 and 22 are made paired. On the base beam 16 by means of hydraulic jacks, feed 23 and swing 24, fix the conveyor belt 9.

The technological cycle for excavation of coal under shield 1 starts from dredging ditch 2 near the soil of the reservoir by means of a conveyor belt 9, operating with hydraulic jacks 23 and 24 and forming a supporting pillar 4. At the same time, the berm is dredged - a horizontal platform 6 from the roof of the reservoir by means of excavation machines 5 and transporting the coal repulsed by the conveyor 8 into the ditch 2. from where coal is transported by conveyor-sided 9 to the coal-fired furnace. At this time, the shield overlap 1

(all its sections 11) along the hanging side of the reservoir are supported with coal support entirely 3, and on the lying side of the reservoir the overlap is supported by hydrochip 10 through the support hydrostatic 20 and the boot 21 located on the ledge.

After the ditch 2 has been removed, a basic beam 16 is shifted to the new step of the slide. The hydraulic jacks 17 and 18 are moved apart, and the hydraulic jacks 22 are reduced synchronously with the shifting of the base beam 16. Now the shield 1 is supported through the base / tail 16 and the hydraulic bolts 17 of the slide on the supporting coal target 4 at the lying side of the reservoir and on the supporting hydroracks 20,

0 which can be unloaded and rearranged to a new forward position, for which along the entire front (along the entire length of the slaughter), when ditching 2 with the conveyor belt 9, a small step above the rear pillar 4 is removed

5 at the same time with its design. The ledge is located on the opposite side of the rear sight 4 of the ditch 2.

After shifting the uprights 20 to a new position, they start digging the coal.

0 in the reference pillar Z at the vis of which the sides of the reservoir. The excavation machine 5 takes up the position as shown in Figs. 1 and 4. Mobile Hydraulic support 7, supporting shield 1, consists of three two-post

5 sections installed one after another along the bottom. The removal machine 5 is placed on a special rotary shelf between the first two sections. As the coal is dredged in the rear sight 3 and the support sections move

0 unloads the last end section of the lining 7 and section 11 of the shield lining

I move to a new position. At the wall of which the side of the seam section 11 sits, destroying the trimmed sight pillar 3, and

5, to the lying side of the formation, the shield section 11 is pulled by hydraulic jacks 17 to support the shifted base beam 16 16. At the same time, the shield section is moved, relatively to the excavation step, by the conveyor angle 9 - 0.7 m.

0 When moving (shifting) sections

The cylindrical axes 12 of the intersectional hinges roll on the vertical sides of the nakatnik package, first coming to the lower position of the section to be moved and to the upper position of the moving section, returning to the middle position after moving both adjacent sections. In this case, the cable ties 13 occupy the positions shown in Fig. 4.

The excavation of coal in the supporting pillars 3 and the movement of all sections of the shield complete the technological cycle of excavation of coal under the shield during the development of a thick formation.

At the end of the shield post, all excavation equipment and hydroficated lining are dismantled and transferred back into service after repair.

Claims (1)

The invention of the Method of developing powerful steep and inclined coal seams, including mechanized excavation with coal excavation machines under shield protection, formation of supporting pillars near the roof and soil of the reservoir, development of a ventilation ditch, testing of supporting pillars with subsequent lowering of the shield and transportation of coal from the coal-fired furnaces , characterized in that, in order to increase the efficiency of coal extraction by providing control of the movement of the shield, the ditches are carried out at the soil of the reservoir, while forming a support pillar in the soil of the reservoir to form a ledge on the opposite side of the ditch along the entire length at the same time as the ditch, the ditches form a horizontal berm from the roof of the reservoir, from the side of the soil of the reservoir, the shield is supported by a mechanized support, which is installed on the ledge and the supporting pillar of the soil of the reservoir, and on the side of the roof of the reservoir by a mechanized support, , the control of the movement of the shield from the side of the soil of the reservoir is carried out by the movement of the mechanized support after the ditch has been dredged by the shifting step, after which the coal is dredged in the supporting rear sight at the roof of the reservoir and as it is excavated, the control of the shield movement is performed by unloading mechanized roof support on the horizontal berm. J / J - BUT with ed Oi about. BUT f2 . -Jv 5 h- , ". i ,, 12